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Meagan Collins Honors Program Senior Thesis Project 11 March 2019

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Meagan Collins Honors Program Senior Thesis Project 11 March 2019 Collins 1 Meagan Collins Honors Program Senior Thesis Project 11 March 2019 The Colonization of Mars: Law, Politics and Ethics An individual’s curiosity and will to question a societal norm can lead to expansive discovery and enhanced knowledge. In 2013, a small private Dutch company conceptualized a project to initiate steps working towards colonizing the planet Mars. While space exploration and scientific advancements are accurate reasons to endorse a project such as the Mars One Mission and one can consider the ways this could enhance or benefit human life on Earth, it is not imperative nor feasible. Through extensive research and investigation, I will explore the concepts of space law and international law as they relate to the colonization of Mars. Additionally, I will utilize political and ethical theories to evaluate what this mission would entail and the impact it would have on humanity. It is important to realize that while scientific advancements and space exploration do not drive the existence of the human race on Earth, both play a large part in the progression and development of humanity as we know it. In this paper I will argue that while space exploration and expansion can further advance scientific discovery, this is not what drives the existence of the human race on Earth. Taking into consideration the legal, political, and ethical aspects of the Mars One Mission expose the lack of technology and funding required for success. Collins 2 What Is the Mars One Mission? The first step to addressing this argument is understanding what the Mars One Mission is and exploring its purpose. The main stated goal of the project is to establish a human settlement on Mars, which would be a giant leap for humankind. According to the Mars One Mission’s main website, “Human settlement on Mars will aid our understanding of the origins of the solar system, the origins of life and our place in the universe. As with the Apollo Moon landings, a human mission to Mars will inspire generations to believe that all things are possible, anything can be achieved” (“Current Status”). This mission statement makes the assertion that exploring space and colonizing another planet are beneficial to mankind. It is interesting to read such discoveries will clarify our place in this universe. Mars is currently the only planet with prospects of supporting human life. Successful completion of this mission would allow the human race to become a multiplanetary species. The driving force behind this mission consists of two entities: “the Dutch not-for-profit Stitching Mars One (Mars One Foundation) and Swiss publicly trading Mars One Ventures AG [FRA: KCC], ISIN: CH0132106482 (Mars One Ventures). The Mars One Foundation implements and manages the mission and owns the mission hardware” (“Current Status”). This foundation is responsible for selecting and training the crew members who would embark on this journey, as well as building a group of experts who can contribute to the progress and success of the mission. Mars One Ventures holds the exclusive monetization rights around the mission, from merchandise, ads on video content, broadcasting rights, Intellectual Property, and many more. While different components of this mission are falling into place, a big obstacle which stands in Collins 3 the way is funding. Obtaining enough money to successfully complete this project proves to be the ultimate challenge. The astronauts who would be going to Mars and never returning to Earth are a vital component of this project. It is wild to consider leaving Earth and never returning, however there are hundreds of people signed up for an astronaut position in this mission. These individuals are in a position to conceptualize a completely new existence on Mars which would be exclusive from everything and everyone they know in this world. Although people may register to participate, they are not guaranteed to travel to the red planet. Five main characteristics Mars One is looking for in their astronauts include: resiliency, adaptability, curiosity, ability to trust, and creativity/resourcefulness. There is also a minimum age requirement of 18 years or older. There are specific standards, extensive qualifications and trainings which must be met and completed. A discussion of qualifications would include: The astronauts must be intelligent, creative, psychologically stable and physically healthy. In spaceflight missions, the primary personal attributes of a successful astronaut are emotional and psychological stability, supported by personal drive and motivation. This is the foundation upon a mission must be built, where human lives are at risk with each flight. Once on Mars, there are no means to return to Earth. Mars is home. A grounded, deep sense of purpose will help each astronaut maintain his or her psychological stability and focus as they work together toward a shared and better future. Mars One cannot stress enough the importance of an applicant’s capacity for Collins 4 self-reflection. Without this essential foundation, the five key characteristics listed below cannot be utilized to the fullest potential. (“Astronaut Requirements”) While reviewing this entry, it is intriguing to read one of the qualifications is “a grounded, deep sense of purpose,” which leads to the questioning of set purpose. For people to take on such a role, they must believe that their purpose in life is to travel to Mars for exploration and potential colonization. This involves leaving behind family, friends, and everything that is familiar in order to start a new life on a new planet. Developing a new life and existence on Mars may in fact be the source of meaning in these people’s lives, but survival is not guaranteed. In fact, the chances of survival are low. It is also important to consider the physical toll this will have on a person. While they prepare for what it will be like traveling to Mars for six months and participate in simulations of what it will be like once they are on the planet, things will of course be different when they are actually happening. The current six-month rotation on-board the International Space Station was partly designed so that it reflects the time taken to get to Mars, resulting in greater knowledge on what state an individual would arrive at Mars in. Physiological effects aboard the ISS range from muscle atrophy to osteoporosis and negative effects on the balance and cardiovascular system. With these mitigated for to some extent, such signs of the body adjusting to daily life without gravity are in synchrony with those likely to be experienced on a journey to Mars. (“How Will Living On Mars Affect Our Human Body?”) Collins 5 The concept of gravity plays an important part in this. Mars only has 38% of the gravity Earth does. While this will make landing a bit easier, over time the body may suffer because of the drastic difference. It is stated that “Adjusting to this lower level of gravitational pull on Mars may cause a physiological change in the astronauts’ bone density, muscle strength, and circulation making it impossible to survive under Earth conditions if they were to ever return” (“How Will Living On Mars Affect Our Human Body”). Air Law and International Law One important concept to consider is who would have control of Mars and how that would be determined. The question could be raised if another planet acts as another territory or if it would be separate from the legal system of international law put in place on Earth. Exploring the key principles of air law unveil clarity and possible propositions for incorporating Mars into the international system. The common law precedent pertaining to private property rights was established by Lord Coke in the case Bury v. Pope, stating that “private property rights attached to real estate extend also into the air above, since … “the earth hath in law a ayre and all other things, even up to heaven, for cujus est solum ejus est usque ad coelum” which has been translated to “he who owns the land owns up into the sky” (Schick, 681). While this is a more classical idea and does not pertain to modern law there is still appreciation for this doctrine. According to practices of Roman Law, there are limitations to certain rights in the air above both public and private property, but it is clearly understood these rights don’t extend “up into heaven” rather are used for “protecting the legitimate use of the land against unauthorized interference from the air” (Schick, 681). Collins 6 Incorporating interpretation of the Roman precedent and the private law practice, in both common law and civil law countries, “it is not difficult to see why the claims of States to exclusive jurisdiction over their national air space have been justified in modern times with reference to well-established custom, and particularly to the cujus est solum doctrine” (Schick, 682). It is established that jurisdiction in air space of both public and private property was to “reach “into the sky” –ad coelum—only as far as was necessary to protect such … lands from unauthorized interference from above” (683). This is supported by Paul’s famous rule amongst other passages of famous jurists such as Marcian, Celsus, and Ulpian, who expanded on the concept of air and sea being common to mankind and beyond the exclusive State authority (683). While the origins of space law according to varying legal systems comprise the idea of having control of land and air, this altered throughout history with advancements in international law concepts for the protection of states. Different legal documents and treaties present altering stances on this issue. For example, Article 1 of the Chicago convention states, ““every State has complete and exclusive jurisdiction over the airspace above its territory.” As in the Paris convention of 1919, the term “airspace” is not defined … subsequent technical additions to the convention, such as annexes 6,7, and 8 retain the description of aircraft given at Paris as “any machine which can derive support in the atmosphere from reactions of the air” (Schick, 686).
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